Beacon light with reflector and light-emitting diodes

ABSTRACT

A light-emitting diode (LED) reflector optic includes a reflector having a reflector having a plurality of reflecting surfaces, wherein each one of the plurality of reflecting surfaces is associated with at least one optical axis, each reflecting surface comprising a cross-section that is projected along a curved trajectory and a plurality of LEDs, wherein each one of the plurality of LEDs is positioned in a line parallel to the cross-section of an associated one of the plurality of reflecting surfaces and relative to the associated reflecting surface of the plurality of reflecting surfaces such that a central light-emitting axis of each one of the plurality of LEDs is angled relative to the at least one optical axis of the associated reflecting surface of the plurality of reflecting surfaces at about 90° and such that each of the reflecting surfaces redirects and collimates a light output of a respective each one of the plurality of LEDs at an angle of about 90° with respect to the central light emitting axis of each one of the plurality of LEDs, wherein each one of the plurality of reflecting surfaces receives light from each one of the plurality of LEDs from a focal distance of the associated one of the plurality of reflecting surfaces.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.11/300,770, filed on Dec. 15, 2005, which is a continuation-in-part ofU.S. patent application Ser. No. 11/069,989, filed on Mar. 3, 2005,which is hereby incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to a light source, and moreparticularly to a light-emitting diode (LED)-based beacon light.

2. Description of the Related Art

A beacon light such as, for example, an aircraft obstruction light, canbe used to mark an obstacle that may provide a hazard to aircraftnavigation. Beacon lights are typically used on buildings, towers, andother structures taller than about 150 feet. Previous beacon lightsgenerally exhibit relatively poor energy efficiency, which can prohibitthe use of solar panels to power the beacon light. Previous beaconlights may also contribute to light pollution, i.e., direct light atangles undesirably above and below a specified plane. Previous beaconlights may also be too large and heavy for climbers to carry andtherefore may require additional machinery or manpower to be hoistedinto position.

SUMMARY OF THE INVENTION

Various deficiencies of the prior art are addressed by the presentinvention, one embodiment of which is a beacon light having alight-emitting diode (LED) reflector optic. The LED reflector opticcomprises a reflector having a plurality of reflecting surfaces, whereineach one of said plurality of reflecting surfaces is associated with atleast one optical axis, each reflecting surface comprising across-section that is projected along a curved trajectory and aplurality of LEDs, wherein each one of the plurality of LEDs ispositioned in a line parallel to said cross-section of an associated oneof said plurality of reflecting surfaces and relative to said associatedreflecting surface of said plurality of reflecting surfaces such that acentral light-emitting axis of each one of the plurality of LEDs isangled relative to the at least one optical axis of said associatedreflecting surface of the plurality of reflecting surfaces at about 90°and such that each of the reflecting surfaces redirects and collimates alight output of a respective each one of the plurality of LEDs at anangle of about 90° with respect to the central light emitting axis ofeach one of the plurality of LEDs, wherein each one of the plurality ofreflecting surfaces receives light from each one of the plurality ofLEDs from a focal distance of said associated one of said plurality ofreflecting surfaces.

In one embodiment, the at least one LED is positioned such the centrallight-emitting axis is angled relative to the at least one optical axisat about 0°. In one embodiment, the about 0° has a tolerance of ±30°.

One embodiment of a method for transmitting light from a plurality oflight emitting diodes (LEDs) is disclosed. In one embodiment, the methodcomprises arranging a plurality of reflecting surfaces relative to eachother, each of the plurality of reflecting surfaces comprising across-section projected along a curved trajectory, positioning each oneof the plurality of LEDs in a line parallel to said linearly projectedcross-section of an associated one of the plurality of reflectingsurfaces, wherein the positioning step angles a central light-emittingaxis of each one of the plurality of LEDs relative to at least oneoptical axis associated with the plurality of reflecting surfaces atabout 90° such that each of the reflecting surfaces redirects andcollimates a light output of a respective each one of the plurality ofLEDs at an angle of about 90° with respect to the central light emittingaxis of each one of the plurality of LEDs, wherein each one of theplurality of reflecting surfaces receives light from each one of theplurality of LEDs from a focal distance of said associated one of saidplurality of reflecting surfaces and transmitting light from theplurality of LEDs onto the associated one of the plurality of reflectingsurfaces.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the presentinvention can be understood in detail, a more particular description ofthe invention, briefly summarized above, may be had by reference toembodiments, some of which are illustrated in the appended drawings. Itis to be noted, however, that the appended drawings illustrate onlytypical embodiments of this invention and are therefore not to beconsidered limiting of its scope, for the invention may admit to otherequally effective embodiments.

FIG. 1 depicts a perspective view of an embodiment of the beacon lightaccording to the present invention;

FIG. 2 depicts a perspective view of an embodiment of the LED reflectoroptic of the beacon light depicted in FIG. 1;

FIG. 3 depicts a perspective view of an embodiment of the angularrelationship between the optical axis associated with the reflectingsurface of the LED reflector optic depicted in FIG. 2, the central lightemitting axis of the LED of the LED reflector optic, and the extrusionaxis of the reflecting surface;

FIG. 4 depicts a partial perspective view of an embodiment of the beaconlight depicted in FIG. 1;

FIG. 5 is a graph depicting a representation of the intensity, versusangular displacement vertically from the optical axis, of light emittedfrom an embodiment of the beacon light depicted in FIG. 1;

FIG. 6 depicts a sectional top view of an embodiment of the reflector ofthe LED reflector optic depicted in FIG. 2;

FIG. 7 is a graph depicting a representation of the relative intensity,versus angular displacement, of light reflected from three differentadjacent reflecting surfaces, and the sum thereof, of an embodiment ofthe LED reflector optic depicted in FIG. 2;

FIG. 8 depicts a partial sectional side view of an embodiment of the LEDreflector optic depicted in FIG. 2;

FIG. 9 is a graph depicting a representation of relative lightintensity, versus angular displacement, for light typically emitted fromthe LED, and for light reflected by the embodiment of the LED reflectoroptic depicted in FIG. 8;

FIG. 10 depicts an embodiment of an alternative arrangement of the LEDand reflecting surface;

FIG. 11 is a graph depicting a representation of relative lightintensity, versus angular displacement, for light typically emitted fromthe LED, and for light emitted from the embodiment of the alternativearrangement of the LED and reflecting surface depicted in FIG. 10;

FIG. 12 depicts a partial side view of an embodiment of the LEDreflector optic depicted in FIG. 2, showing mathematically simulated raytraces;

FIG. 13 depicts a partial front view of the embodiment of the LEDreflector optic depicted in FIG. 12, showing the same ray traces shownin FIG. 12 from another view;

FIG. 14 depicts a partial side view of an embodiment of an alternativereflector having an alternative reflecting surface, showingmathematically simulated ray traces;

FIG. 15 depicts a partial front view of the embodiment of thealternative reflector having the alternative reflecting surface depictedin FIG. 14, showing the same ray traces shown in FIG. 14 from anotherview;

FIG. 16 a depicts a perspective view of an embodiment of a segment,having the reflecting surface, of an embodiment of the LED reflectoroptic depicted in FIGS. 12 and 13;

FIG. 16 b depicts a partial perspective view of an embodiment the LEDreflector optic having an embodiment of the alternative reflectorcomprising the alternative reflecting surface depicted in FIGS. 14 and15;

FIG. 17 depicts a perspective view of an embodiment of the LED reflectoroptic having an embodiment of the alternative reflector comprising thealternative reflecting surface;

FIG. 18 depicts a partial sectional view of an embodiment of the LEDreflector optic comprising at least one of: a glass, a plastic or atransparent material;

FIG. 19 depicts a partial sectional side view of an embodiment of theLED reflector optic having a faceted reflecting surface; and

FIG. 20 depicts a partial perspective view of an embodiment of thebeacon light having a plurality of the LED reflector optics.

To facilitate understanding, identical reference numerals have beenused, where possible, to designate identical elements that are common tothe figures.

DETAILED DESCRIPTION

FIG. 1 depicts a perspective view of a beacon light 20 according to oneembodiment of the present invention. The beacon light 20 comprises anLED reflector optic 24. In one embodiment, the beacon light 20 alsocomprises a shield 64, a pedestal 68, a base 72, an electricalconnection 76 to the beacon light 20, and circuitry (not shown) to drivethe beacon light 20. In one embodiment, the drive circuitry (not shown)is capable of strobing the LED reflector optic 24. The pedestal 68supports the LED reflector optic 24, and the base 72 provides a meansfor attaching the beacon light 20 to a structure.

FIG. 2 depicts a perspective view of an embodiment of the LED reflectoroptic 24 according to the present invention. In one embodiment, the LEDreflector optic 24 comprises a reflector 28 having a plurality ofreflecting surfaces 32, i.e., a segmented reflector 28.

Each reflecting surface 32 comprises a cross-section 40 (as depicted inFIG. 8) which is projected along an associated linear extrusion axis 44.In one embodiment, the linearly projected cross-section 40 comprises aconic section. A conic section provides an advantageous reflected lightintensity distribution. In one embodiment, the cross-section 40 of thereflecting surface 32 comprises at least one of: a conic or asubstantially conic shape. In one embodiment, the conic shape comprisesat least one of: a hyperbola, a parabola, an ellipse, a circle, or amodified conic shape.

Each reflecting surface 32 has an associated optical axis 36. In oneembodiment, each reflecting surface 32 reflects a beam of light havingan angular distribution horizontally symmetric to the associated opticalaxis 36, i.e. symmetric about the associated optical axis 36 indirections along the extrusion axis 44.

For each reflecting surface 32, the LED reflector optic 24 comprises atleast one associated LED 52. The LED 52 has a central light-emittingaxis 56, and typically emits light in a hemisphere centered andconcentrated about the central light-emitting axis 56. The LED 52 ispositioned relative to the associated reflecting surface 32 such thatthe central light-emitting axis 56 of the LED 52 is angled at apredetermined angle θ_(A) relative to the optical axis 36 associatedwith the reflecting surface 32. In a preferred embodiment, θ_(A) ahas avalue of about 90°. In one embodiment, the about 90° has a tolerance of±30°, i.e., from 60° to 120°.

In one embodiment, for a specific reflecting surface 32 and associatedLED 52, the central light-emitting axis 56 of the LED 52, the opticalaxis 36 associated with the reflecting surface 32, and the extrusionaxis 44 of the reflecting surface 32 form orthogonal axes of a 3-axeslinear coordinate system. Namely, the central light-emitting axis 56,the optical axis 36, and the extrusion axis 44 are mutuallyperpendicular. FIG. 3 depicts a representation of the mutuallyperpendicular relationship between the central light-emitting axis 56,the optical axis 36, and the extrusion axis 44. In FIG. 2, θ_(B) is theangle between the optical axis 36 and the extrusion axis 44, and θ_(C)is the angle between the central light emitting axis 56 and theextrusion axis 44. In one embodiment, the mutually perpendicularrelationship between the central light-emitting axis 56, the opticalaxis 36, and the extrusion axis 44 is approximate. For example, each ofthe central light-emitting axis 56, the optical axis 36, and theextrusion axis 44 can be angled at 90° from each of the other two axes,with a tolerance, in one embodiment, of ±30°.

In one embodiment, for each reflecting surface 32, the LED reflectoroptic 24 comprises a plurality of associated LEDs 52. In one embodiment,the plurality of associated LEDs 52 are arranged along a line, asdepicted in FIG. 2, parallel to the extrusion axis 44 of the reflectingsurface 32. In one embodiment, the plurality of associated LEDs 52 arestaggered about a line. For example, in one embodiment, the plurality ofassociated LEDs 52 are staggered about a line, with the staggeringcomprising offsetting the LEDs 52 from the line by a predetermineddistance in alternating directions perpendicular to the line. Also, inone embodiment, the LED 52, or the plurality of LEDs 52, are positionedat the focal distance of the reflecting surface 32.

FIG. 4 depicts a partial perspective view of an embodiment of the beaconlight 20 in which the beacon light 20 emits light outward over a 360°angular distribution about a central axis 88 of the reflector 28 of theLED reflector optic 24. Such a 360° angular distribution of reflectedlight may be a requirement for the beacon light 20 to provideobstruction warning in all directions.

The light emitted from the beacon light 20 has a predetermined beamspread θ_(D), as depicted in FIG. 4. The beam spread θ_(D) is the angle,vertically perpendicular to the optical axes 36 of the reflectingsurfaces 32, over which the intensity of the emitted light is greaterthan 50% of the peak intensity of the emitted light. In a preferredembodiment, the beacon light 20 has a beam spread θ_(D) of less than 3°.In another embodiment, the beacon light 20 has a beam spread θ_(D) ofless than 10°.

FIG. 5 is a graph depicting a representation of the light intensity,versus angular displacement vertically perpendicular to the optical axes36, emitted from an embodiment of the beacon light 20. FIG. 5 shows thebeam spread θ_(D) for this embodiment is approximately 3°, i.e., about1.5° on either side of a plane containing the optical axes 36.

The plurality of reflecting surfaces 32 of the reflector 28 are arrangedso that each of the associated extrusion axes 44 is angled relative tothe extrusion axis 44 of another reflecting surface 32. In oneembodiment, the plurality of extrusion axes 44 occupy a single plane andintersect each other to outline a polygon. Namely, a top viewcross-section of the reflector comprises a perimeter which is a polygon.FIG. 6 depicts a sectional top view of an embodiment of the reflector28, showing the plurality of associated extrusion axes 44 intersectingeach other to form a hexagon. Such an embodiment achieves the 360°angular distribution, relative to the central axis 88 of the reflector28, of light emitted from the LED reflector optic 24. Each reflectingsurface 32 reflects light in the direction of the optical axis 36associated with that reflecting surface 32, and through an angulardistribution horizontally symmetric to and centered to the optical axis36.

Although FIG. 6 depicts a polygon embodiment of the reflector 28 havingsix reflecting surfaces 32, in another polygon embodiment the reflector28 has at least three reflecting surfaces 32.

In one embodiment, each horizontal angular distribution of reflectedlight associated with a specific reflecting surface 32 overlaps thehorizontal angular distribution of reflected light associated with anadjacent reflecting surface 32. FIG. 7 is a graph depicting arepresentation of the relative intensity, versus horizontal angulardisplacement, of light reflected from three different adjacentreflecting surfaces 32, and the sum thereof. The thick solid line ofFIG. 7 represents the overall intensity of light emitted from the LEDreflector optic 24, including light reflected from all of the threeadjacent reflecting surfaces 32. The thin solid line represents theintensity of light reflected from the reflecting surface 32 associatedwith the optical axis 36 about which the angular displacement of FIG. 7is centered, i.e. the reflecting surface 32 having the optical axis at0° as shown in FIG. 7. The dotted and dashed lines of FIG. 7 representthe intensity of light reflected from the two reflecting surfaces 32adjacent and connected to the first reflecting surface 32. FIG. 7 showsthat the light reflected from each reflecting surfaces 32 overlaps thelight reflected from adjacent reflecting surfaces 32 to form an overallreflection of light from the reflector 28 which has a more uniformintensity profile, versus angular displacement, than the individualintensity profiles of light reflected from the individual reflectingsurfaces 32.

In one embodiment, the intersection of the plurality of extrusion axes44 does not necessarily outline a polygon. In one embodiment, lightemitted from the LED reflector optic 24 does not have a 360° angulardistribution relative to the central axis 88 of the reflector 28. Suchan embodiment may instead achieve, for example, a 180° angulardistribution.

In one embodiment, the plurality of reflecting surfaces 32 of thesegmented reflector 28 are connected together.

The utilization of light emitted by the LED 52 by one embodiment of theLED reflector optic 24 provides an advantage of the present invention.To further understand this advantage, the utilization of light by oneembodiment of the LED reflector optic 24 can be compared to theutilization of light in an alternative relative positioning of the LED52 and the reflecting surface 32.

FIG. 8 depicts a partial sectional side view of an embodiment of the LEDreflector optic 24. In the embodiment shown in FIG. 8, the reflectingsurface 32 has a conic cross-section, and the central light-emittingaxis 56 of the LED 52 is in the same plane as the shown cross-section.FIG. 8 also shows the angle θ_(E) over which light, emitted from the LED52, is reflected by the reflecting surface 32.

FIG. 9 is a graph depicting a representation of the relative intensityof light, versus angular displacement in the plane of FIG. 8, for lighttypically emitted by the LED 52, and for light reflected by thereflecting surface 32 of the LED reflector optic 24 shown in FIG. 8. Thesolid line of FIG. 9 represents the light intensity distributiontypically emitted by the LED 52, i.e., without the reflecting surface 32present, versus angular displacement relative to the central lightemitting axis 56. The light intensity distribution emitted by the LED 52is typically lambertian. However, other light intensity distributionsmay also benefit from the present invention. The light intensitydistribution emitted by the LED 52 includes light over about 180°, i.e.,about 90° on either side of the central light-emitting axis 56. Thedotted line of FIG. 9 represents the portion of the light intensitydistribution emitted by the LED 52 which is reflected by the reflectingsurface 32 positioned relative to the LED 52 as shown in FIG. 8. Thedotted line shows that light over the angle θ_(E), i.e., about 135°, ofthe angular distribution of the LED emission is reflected by thereflecting surface 32. The angle θ_(E) includes about 90° on one side ofthe central light-emitting axis 56 and about 45° on the other side ofthe central light-emitting axis 56. The portion of the LED emissionwhich is reflected by the reflecting surface 32, i.e. the portion of theLED emission within angle θ_(E), is utilized light. The portion of theLED emission which is not reflected by the reflecting surface 32, i.e.the portion of the LED emission outside the angle θ_(E), is unutilizedlight.

FIG. 10 depicts an embodiment of an alternative relative positioning ofthe LED 52 and the reflecting surface 32. In this alternativearrangement, the central light-emitting axis 56 of the LED 52 isarranged to be parallel to the optical axis 36 of the reflecting surface32.

FIG. 11 is a graph depicting a representation of the relative intensityof light, versus angular displacement in the plane of FIG. 10, for thetypical light emission by the LED 52, and for light emitted by thealternative arrangement of the LED 52 and the reflecting surface 32depicted in FIG. 10. The solid line of FIG. 11 represents the typicallight intensity distribution emitted by the LED 52 without the presenceof the reflecting surface 32. The dotted line of FIG. 11 represents theportion of the typical LED light intensity distribution which isutilized by the arrangement depicted in FIG. 10. The portion of lightutilized comprises a first portion over an angle θ_(G), centered aboutthe central light-emitting axis 56 and not reflected by the reflectingsurface 32, and a second portion over an angle θ_(F) on either side ofthe central light-emitting axis 56, i.e., from 90° to 90°−θ_(F), andfrom −90° to −90°+θ_(F), wherein θ_(F) is about 45°. The first portionis utilized because if falls within the desired beam spread θ_(D) of thebeacon light 20, and in one embodiment angle θ_(G) equals the beamspread θ_(D). The second portion is utilized because it is reflected bythe reflecting surface 32 to also fall within the desired beam spreadθ_(D) of the beacon light 20. An unutilized portion of the typical lightintensity distribution which is over angles, relative to the centrallight emitting axis 56, from 0.5 θ_(G) to 90°−θ_(F), and from −0.5 θ_(G)to −90°+θ_(F), is not utilized because it is not reflected by thereflecting surface 32. The unutilized portion of the typical lightintensity distribution emitted by the LED 52 from −0.5 θ_(G) to−90°θ_(F) is undesirable and may be considered to be light pollutionbecause it typically points downward towards the ground from, forexample, a relatively high position.

Thus, FIG. 11 shows that the alternative relative positioning of the LED52 and the reflecting surface 32 depicted in FIG. 10 does not utilizethe majority of the high intensity central portion of the lightintensity distribution typically emitted by the LED 52. By comparison,the embodiment of the LED reflector optic 24 of the present invention asdepicted in FIG. 8 utilizes the majority of the high intensity centralportion of the light intensity distribution typically emitted by the LED52. A numerical comparison of the light utilizations depicted by FIGS. 9and 11 shows that the area under the dotted line in FIG. 9 is about 45%greater than the area under the dotted line in FIG. 11. Thus, theembodiment of the LED reflector optic 24 depicted in FIG. 8 providesapproximately a 45% increase in light utilization from a single LED 52,in comparison to the alternative arrangement depicted in FIG. 10.

Furthermore, the embodiment of the LED reflector optic 24 depicted inFIG. 8 provides the possibility of the reflector 28 having a reducedsize relative to the embodiment of the alternative arrangement depictedin FIG. 10. For example, the reflector 28 depicted in FIG. 8 has a sizewhich is reduced by about half in comparison to the embodiment of thereflector 28 depicted in FIG. 10.

The utilization of light by the embodiment of the LED reflector optic 24depicted in FIG. 8 of the light emitted by the LED 52 provides anadvantage of the present invention. However, the present inventionnonetheless provides other advantages, and thus one embodiment of theLED reflector optic 24 comprises the LED 52 positioned such that thecentral light-emitting axis 56 is angled at the angle θ_(A) having avalue of about 0°, as depicted in FIG. 10. In one embodiment, the about0° has a tolerance of ±30°, i.e., from −30° to 30°. In anotherembodiment, the about 0° has a tolerance of +10°, i.e., from −10° to10°.

An exemplary illustration of another advantage provided by an aspect ofthe present invention is depicted in FIGS. 12-15. The projection of thecross-section 40 of the reflecting surface 32 along the linear extrusionaxis 44 advantageously provides increased collimation of the reflectedlight.

FIG. 12 depicts a partial side view of an embodiment of the LEDreflector optic 24. In the embodiment of FIG. 12, the LED 52 is locatedat the focal distance of the reflecting surface 32 in a plane 47(depicted in FIG. 16A). FIG. 12 also depicts mathematically simulatedray traces 57 showing the path of light traveling from the LED 52 to thereflecting surface 32 and outward from the reflector 28. Ray tracing isa technique that uses 3-D computer modeling and geometric optics toaccurately determine the light path. FIG. 12 shows the ray traces 57 areparallel to the optical axis 36 in the depicted embodiment of the LEDreflector optic 24.

FIG. 13 depicts a partial frontal view of the embodiment of the LEDreflector optic 24 depicted in FIG. 12, showing the same mathematicallysimulated ray traces 57 as FIG. 12, but from another view. Because thereflecting surface 32 of FIGS. 12 and 13 is a projection of thecross-section 40 along the linear extrusion axis 44, light travelingfrom the LED 52 to the reflecting surface results in well collimatedlight reflected parallel to the optical axis 36 of the reflectingsurface 32.

By comparison, FIG. 14 depicts a partial side view of an embodiment ofan alternative reflector 30 having an alternative reflecting surface 34which is an unsegmented reflecting surface 34. The alternativereflecting surface 34 has a cross-section that is projected along acurved trajectory 48 (as depicted in FIG. 17), not a linear axis. In theembodiment of FIG. 14, the LED 52 is located at the focal distance ofthe reflecting surface 32 in the plane 51 (depicted in FIG. 16B). FIG.14 also depicts mathematically simulated ray traces 58 showing the pathof light traveling from the LED 52, to the reflecting surface 32 andoutward from the reflector 28.

FIG. 15 depicts a partial front view of the embodiment of thealternative reflector 30 having the alternative reflecting surface 34depicted in FIG. 14, and showing the same mathematically simulated raytraces 58 as FIG. 14, but from another view. FIGS. 14 and 15 shows thatthe light reflected by the alternative reflector 30 is not as wellcollimated as the light reflected by the reflector 28, as depicted inFIGS. 12 and 13. Light is reflected from the alternative reflectingsurface 34 at angles vertically away from the optical axis 36.

FIG. 16A depicts a perspective view of an embodiment of a segment of thereflector 28 depicted in FIG. 12, and FIG. 16B a partial perspectiveview of an embodiment of the alternative reflector 30 depicted in FIG.14. The increased collimation provided by the reflector 28, incomparison to the alternative reflector 30, can also be betterunderstood in reference to FIGS. 16A and 16B. Generally speaking, aparabolic reflector, for example, receives light originating from itsfocal distance and reflects the light parallel to the optical axis ofthe reflector. If the reflector has the cross-section 40 projected alongthe linear extrusion axis 44, as in the embodiment of the reflector 28depicted in FIG. 16A, then the parabolic system is lost only in thehorizontal direction and is conserved in the vertical direction and thelight will be collimated vertically. For example, considering lightcomprising vector components in the x, y and z directions depicted inFIG. 16A, line 55 demarks the focal length f for the vector component oflight traveling in the y direction, and line 55 is common to the entirelength of the reflector. Therefore the vector component of light emittedby LED 52 in the y direction strikes both plane 54 and plane 47 asarriving from the focal length.

By comparison, if the reflector is revolved, i.e. having thecross-section projected along the curved trajectory 48, as in theembodiment of the reflector 30 depicted in FIG. 16B, then the parabolicsystem is lost in both the horizontal and vertical directions. Forexample, FIG. 16B depicts a line 53 demarking the focal length f for thevector component of light traveling in the y direction, with respect tolight arriving at plane 49, plane 49 being offset and angledhorizontally from the plane 51. FIG. 16B shows that the LED 52 does notfall on the line 53 and thus does not emit a component of light in the ydirection which strikes plane 49 as arriving from the focal length.

Thus, the embodiment of the reflector 28 having the projection of thecross-section 40 of the reflecting surface 32 along the linear extrusionaxis 44 provides increased collimation of reflected light in comparisonto the alternative reflector 30 having the alternative reflectingsurface 34. However, the present invention nonetheless provides otheradvantages, and thus in one embodiment, as depicted in FIG. 17, the LEDreflector optic 24 comprises the alternative reflector 30 having thealternative reflecting surface 34.

The LED reflector optic 24 and the beacon light 20 of the presentinvention provide a more efficient optical system. This more efficientoptical system results in smaller and lighter devices with lower energyconsumption and less light pollution. The more efficient optical systemalso enables greater use of solar power to power the LED reflector optic24 and the beacon light 20.

In one embodiment, the reflecting surface 32 comprises at least one of:a metal or a reflective material. For example, in one embodiment thereflecting surface 32 comprises a reflectorized surface such as, forexample, a surface comprising a layered polymer which reflects light.

In another embodiment, depicted in FIG. 18, the reflector 28 comprisesat least one of: glass, plastic or a transparent material. In theembodiment depicted in FIG. 18, the reflector 28 reflects light usingtotal internal reflection.

The intensity distribution of light emitted from the LED reflector optic24 can be adjusted by modifying the specific shape of the reflectingsurface 32. In one embodiment, the shape of the cross-section 40 of thereflecting surface 32 is defined by the following equation:

$\begin{matrix}{{z = {\frac{{cy}^{2}}{1 + \overset{\_}{{)\mspace{11mu} 1} - {\left( {1 + k} \right)c^{2}y^{2}}}} + {F(y)}}},} & (1)\end{matrix}$

where z is a coordinate along an axis parallel to the optical axis 36, yis a coordinate on an axis perpendicular to both the optical axis andthe extrusion axis, k is a conic constant, c is a curvature, and F(y) isa variable function. FIG. 16A depicts the relationship of the z and ycoordinates, as well as an x coordinate along an axis parallel to theextrusion axis 44, with respect to the reflecting surface 32.

In one embodiment, F(y) is equal to zero, and equation (1) provides aconic cross-section. For example, (k<−1) provides a hyperbola, (k=−1)provides a parabola, (−1≦k≦0) provides an ellipse, (k=0) provides asphere, and (k>0) provides an oblate sphere, which are all forms ofconics. Modifying k and c modifies the shape of the reflecting surface32, and thus also modifies the shape of the light intensity distributionreflected by the reflecting surface 32. The reflected beam may therebybe made more narrow or broad as desired.

In one embodiment, F(y) is not equal to zero, and equation (1) providesa cross-sectional shape which is modified relative to a conic shape byan additional mathematical term or terms. For example, F(y) can bechosen to modify a conic shape to alter the reflected light intensitydistribution in some desirable manner. Also, in one embodiment, F(y) canbe used to provide a cross-sectional shape which approximates othershapes, or accommodates a tolerance factor in regards to a conic shape.For example, F(y) may be set to provide cross-sectional shape having apredetermined tolerance relative to a conic cross-section. In oneembodiment, F(y) is set to provide values of z which are within 10% ofthe values provided by the same equation but with F(y) equal to zero.

In one embodiment, the specific cross-sectional conic shape of thealternative reflecting surface 34 is defined by the following set ofequations:

$\begin{matrix}{\; {{z = \frac{{cr}^{2}}{1 + \overset{\_}{{)\mspace{11mu} 1} - {\left( {1 + k} \right)c^{2}r^{2}}}}},{and}}} & (2) \\{{r^{2} = {x^{2} + y^{2}}};} & (3)\end{matrix}$

where x, y, z, c and k are defined as above in regards to equation (1).FIG. 16B depicts the relationship of the x, y and z coordinates withrespect to the alternative reflecting surface 34.

In another embodiment, the cross-sectional shape of the alternativereflecting surface 34 has a shape which comprises the basic conic shapemodified by using additional mathematical terms. For example, in oneembodiment, the cross-sectional shape of the alternative reflectingsurface 34 comprises a polynomial asphere defined by the following setof equations:

$\begin{matrix}{z = {\frac{{cr}^{2}}{1 + \overset{\_}{{)\mspace{11mu} 1} - {\left( {1 + k} \right)c^{2}r^{2}}}}\; + {\sum\limits_{n = 2}^{10}\; {C_{2n}r^{2\; n}}}}} & (4) \\{{r^{2} = {x^{2} + y^{2}}};} & (5)\end{matrix}$

wherein x, y, z, k and c are as defined above, and C is a constant.

In another embodiment, the shape of the cross-section 40 of thereflecting surface 32 is defined by fitting a curve, such as a splinefit, to a set of points. In one embodiment, the spline fit is used toapproximate the conic or substantially conic cross-sectional shape ofone embodiment of the cross-section 40.

In another embodiment, as depicted in FIG. 19, the reflector comprises areflecting surface which is a faceted surface 32 a which has a shapewhich approximates a conic shape. The faceted surface 32 a comprises aplurality of individual planar facets 92. Collectively, the plurality ofindividual planar facets 92 approximate a conic shape, with theapproximation becoming more accurate as the individual planar facets 92are made smaller.

In one embodiment, the beacon light 20 comprises a plurality of LEDreflector optics. For example, FIG. 20 depicts a partial perspectiveview of an embodiment of the beacon light 20 which comprises a pluralityof LED reflector optics 24 stacked on top of each other.

A method of using the LED reflector optic 24 or the beacon light 20comprises arranging a plurality of the reflecting surfaces 32 relativeto each other, each of the plurality of reflecting surfaces 32comprising the linearly projected cross-section 40. The method alsocomprises positioning at least one LED 52 relative to at least one ofthe plurality of reflecting surfaces 32, wherein the positioning stepangles the central light-emitting axis 56 of the at least one LED 52relative to at least one optical axis 36 associated with the pluralityof reflecting surfaces 32 at about 90°. The method also comprisestransmitting light from the at least one LED 52 to the at least one ofthe plurality of reflecting surfaces 32. In one embodiment of themethod, the about 90° has a tolerance of ±30°.

In one embodiment of the method, the at least one LED 52 comprises aplurality of LEDs 52, the at least one optical axis 36 comprises aplurality of optical axes 36, and the positioning step comprisespositioning each of the plurality of LEDs 52 relative to a respectiveone of the plurality of optical axes 36 at about 90°. In one embodimentof the method, each reflecting surface 32 comprises a cross-section 40projected along a linear extrusion axis 44, and the arranging stepcomprises arranging the plurality of reflecting surfaces 32 relative toeach other so that a plurality of the linear extrusion axes 44 areangled relative to each other.

In one embodiment, the reflector optic 24 comprises a plurality ofreflecting means 32 for reflecting light in the direction of at leastone optical axis 36, each reflecting means 32 comprising a means forreceiving light along a linearly projected cross-section 40. The opticalso comprises at least one light emitting means 52 for emitting ahemisphere of light, the at least one light emitting means 52 positionedsuch that a central light-emitting axis 56 of the at least one lightemitting means 52 is angled relative to the at least one optical axis 36at about 90°. In one embodiment of the optic 24, the about 90° has atolerance of ±30°.

The present invention has been generally described within the context ofthe LED reflector optic 24 and the beacon light 20. However, it will beappreciated by those skilled in the art that while the invention hasspecific utility within the context of the LED reflector optic 24 andthe beacon light 20, the invention has broad applicability to any lightsystem.

While the foregoing is directed to embodiments of the present invention,other and further embodiments of the invention may be devised withoutdeparting from the basic scope thereof, and the scope thereof isdetermined by the claims that follow. Various embodiments presentedherein, or portions thereof, may be combined to create furtherembodiments. Furthermore, terms such as top, side, bottom, front, back,and the like are relative or positional terms and are used with respectto the exemplary embodiments illustrated in the figures, and as suchthese terms may be interchangeable.

1. A light-emitting diode (LED) reflector optic, comprising: a reflectorhaving a plurality of reflecting surfaces, wherein each one of saidplurality of reflecting surfaces is associated with at least one opticalaxis, each reflecting surface comprising a cross-section that isprojected along a curved trajectory; and a plurality of light emittingdiodes (LEDs), wherein each one of the plurality of LEDs is positionedin a line parallel to said cross-section of an associated one of saidplurality of reflecting surfaces and relative to said associatedreflecting surface of said plurality of reflecting surfaces such that acentral light-emitting axis of each one of the plurality of LEDs isangled relative to the at least one optical axis of said associatedreflecting surface of the plurality of reflecting surfaces at about 90°and such that each of the reflecting surfaces redirects and collimates alight output of a respective each one of the plurality of LEDs at anangle of about 90° with respect to the central light emitting axis ofeach one of the plurality of LEDs, wherein each one of the plurality ofreflecting surfaces receives light from each one of the plurality ofLEDs from a focal distance of said associated one of said plurality ofreflecting surfaces.
 2. The LED reflector optic of claim 1, wherein theabout 90° has a tolerance of ±30°.
 3. The LED reflector optic of claim1, wherein each reflecting surface comprises at least one of: a conic ora substantially conic shape.
 4. The LED reflector optic of claim 1,wherein the cross-section that is projected along a curved trajectorycomprises a plurality of the cross-sections that are angled relative toeach other.
 5. The LED reflector optic of claim 4, wherein eachreflecting surface is associated with one of the plurality of opticalaxes, and for each reflecting surface: the associated optical axis, theassociated central light emitting axis, and the curved trajectory areapproximately mutually perpendicular.
 6. The LED reflector optic ofclaim 5, wherein the approximately mutually perpendicular has atolerance of about ±30°.
 7. The LED reflector optic of claim 1, whereinthe cross-section of each reflecting surface comprises a shape which isat least one of: a hyperbola, a parabola, an ellipse, a circle, or amodified conic.
 8. The LED reflector optic of claim 1, wherein at leastone of the plurality of reflecting surfaces comprises a faceted surface.9. The LED reflector optic of claim 1, wherein at least one of theplurality of reflecting surface comprises at least one of: a metal or areflective material.
 10. The LED reflector optic of claim 1, wherein thereflector comprises at least one of: glass, plastic or a transparentmaterial; and wherein the reflector reflects light using total internalreflection.
 11. The LED reflector optic of claim 1, wherein thecross-section that is projected along a curved trajectory of saidplurality of reflecting surfaces of the reflector and each one of theplurality of LEDs are configured to direct light along the optical axiswith a beam spread of less than 10° in a direction perpendicular to thecentral light-emitting axis of each one of the plurality of LEDs. 12.The LED reflector optic of claim 1, wherein the LED reflector opticcomprises a plurality of LED reflector optics.
 13. The LED reflectoroptic of claim 1, wherein said light output is collimated with abeamspread of less than 10°.
 14. The LED reflector optic of claim 1,wherein each one of the plurality of LEDs has a beam spread of about 120degrees and the associated reflecting surface of the plurality ofreflecting surfaces redirects and collimates the light of a respectiveeach one of the plurality of LEDs by receiving the LED from about 90° onone side of the central light-emitting axis and about 45° on a secondside of the central light-emitting axis.
 15. A light-emitting diode(LED) reflector optic, comprising: a reflector having a plurality ofreflecting surfaces, wherein each one of said plurality of reflectingsurfaces is associated with at least one optical axis, each reflectingsurface comprising a cross-section that is projected along a curvedtrajectory; and a plurality of light emitting diodes (LEDs) positionedin a straight line parallel to said linearly projected cross-section ofan associated one of said plurality of reflecting surfaces and relativeto said associated reflecting surface of said plurality of reflectingsurfaces such that a central light-emitting axis of each one of theplurality of LEDs is angled relative to the at least one optical axis ofsaid associated reflecting surface of the plurality of reflectingsurfaces at about 0° and such that each of the reflecting surfacesredirects and collimates a light output of a respective each one of theplurality of LEDs at an angle of about 90° with respect to the centrallight emitting axis of each one of the plurality of LEDs, wherein eachone of the plurality of reflecting surfaces receives light from each oneof the plurality of LEDs from a focal distance of said associated one ofsaid plurality of reflecting surfaces.
 16. The LED reflector optic ofclaim 15, wherein the about 0° has a tolerance of ±30°.
 17. The LEDreflector optic of claim 15, wherein the cross-section that is projectedalong a curved trajectory comprises a plurality of the cross-sectionsthat are angled relative to each other.
 18. A method for transmittinglight from a plurality of light emitting diodes (LEDs), comprising:arranging a plurality of reflecting surfaces relative to each other,each of the plurality of reflecting surfaces comprising a cross-sectionprojected along a curved trajectory; positioning each one of theplurality of LEDs in a line parallel to said linearly projectedcross-section of an associated one of the plurality of reflectingsurfaces, wherein the positioning step angles a central light-emittingaxis of each one of the plurality of LEDs relative to at least oneoptical axis associated with the plurality of reflecting surfaces atabout 90° such that each of the reflecting surfaces redirects andcollimates a light output of a respective each one of the plurality ofLEDs at an angle of about 90° with respect to the central light emittingaxis of each one of the plurality of LEDs, wherein each one of theplurality of reflecting surfaces receives light from each one of theplurality of LEDs from a focal distance of said associated one of saidplurality of reflecting surfaces; and transmitting light from theplurality of LEDs onto the associated one of the plurality of reflectingsurfaces.
 19. The method of claim 18, wherein the about 90° has atolerance of ±30°.
 20. The method of claim 18, wherein said light outputis collimated with a beamspread of less than 10°.
 21. The method ofclaim 18, wherein the arranging step comprises: arranging the pluralityof reflecting surfaces relative to each other so that a plurality of thecross-sections that are projected along a curved trajectory are angledrelative to each other.
 22. A reflector optic, comprising: a pluralityof reflecting means for reflecting light in the direction of at leastone optical axis, each reflecting means comprising a means for receivinglight along a cross-section projected along a curved trajectory; and aplurality of light emitting means for emitting a hemisphere of light,each one of the plurality of light emitting means positioned in a lineparallel to said linearly projected cross-section of an associated oneof said plurality of reflecting means and such that a centrallight-emitting axis of each one of the plurality of light emitting meansis angled relative to the at least one optical axis at about 90° andsuch that each of the plurality of reflecting means redirects andcollimates a light output of a respective each one of the plurality oflight emitting means at an angle of about 90° with respect to thecentral light emitting axis of each one of the plurality of lightemitting means, wherein each one of the plurality of reflecting meansreceives light from each one of the plurality of light emitting meansfrom a focal distance of said associated one of said plurality ofreflecting means.
 23. The reflector optic of claim 22, wherein the about90° has a tolerance of ±30°.
 24. The reflector optic of claim 22,wherein said light output is collimated with a beamspread of less than10°.